Middle School Water Quality Curriculum SynopsisDesign your own wetland science field trip or have WREN staff visit your classroom.Programs address Oregon State Science Standards and Common Core State Learning Standards. Purpose of the Water Quality Curriculum: •    For students to model the scientific method, engineering, math, and social studies practices. •    To explore and solve problems along the Long Tom River Watershed. •    To use tools and technology to collect data and use that data to answer questions.•    To engineer solutions to real-life problems and learn how to resolve water quality disputes in real-life scenarios.  Each lesson can be integrated into our 2-hour tour of the West Eugene Wetlands (WEW). How much time is required for the lesson, the best season, and where the lesson is best experienced is indicated next to the lesson tile._______________________________________________________________________________________________What is a Watershed? Activity/ 50 minutes (Class or WEW):It’s recommended that all classes begin their wetland field study with this fun and interactive, whole-body activity that investigates how vegetation affects the movement of water over land surfaces and identifies best management practices to reduce erosion. Science Standards: MS-ESS2; MS-ESS2-4.    Earth’s Systems: Develop a model to describe cycling of water through earth’s systems driven by energy from the sun and force of gravity._______________________________________________________________________________________________Wetland Soil Study/ 90 minutes (WEW- Fall or Spring):Students will learn the history behind the unique composition of soil in the southern Willamette Valley, discover how wetland soils have an important role in filtering and cleaning the water that runs through them, explore and record the physical characteristics of wetland soil using a Munsell Chart, measure the hydric capacity of different types of soil, and make the connection between soils and water in a wet prairie. Science Standards: MS-ESS2-2.    Earth’s Systems: Construct an explanation based on evidence for how geoscience processes have changed Earth's surface at varying time and spatial scales.Common Core Standards:Mathematics7.EE.B.4.     Use variables to represent quantities in a real-world of mathematical problem, and construct simple equations and inequalities to solve problems by reasoning about quantities.______________________________________________________________________________________________           Water Quality of Amazon Creek/ 90 minutes (WEW- Fall and Spring):Through experimentation and a simulation, students will learn how increases in water acidity have endangered the quality of life for water-based organisms in parts of Eugene. Students will model water molecules under different circumstances, test water samples from Amazon creek for dissolved oxygen, PH, and temperature and learn how these variables impact the quality of life in our waterways.  Science Standards: MS-PS1-1.          Matter and Its Interactions: Develop models to describe the atomic composition of simple molecules  and extended structures.Common Core Standards:Mathematics 6.SP.B.4.            Display numerical data in plots on a number line, including dot plots, histograms, and box plots.7.EE.3.               Solve multiple real-life & mathematical problems posed with positive and negative rational numbers in any form using tools strategically. Apply properties of operations to calculate with numbers in any form. _______________________________________________________________________________________________Flood-Plan Engineering Design/ 90 minutes (WEW or Class- Fall, Winter, Spring):Students will learn about historic floods in the Willamette Valley, and explore flood dynamics by building models of riverbeds and testing their holding capacity. Students will use engineering to design systems that will help prevent flood damage and learn about how human modifications to a river or wetland can alter the floodplain.Science Standards:MS-ESS3-3.     Earth’s & Human Activity: Apply Scientific principles to design a method for monitoring and minimizing a human impact on the environment.MS-ESS3-2.    Earth’s & Human Activity: Analyze and interpret data on natural hazards to forecast future catastrophic events and inform the development of technologies to mitigate their efforts.MS-ETS1-1; 1-4. Engineering Design: Develop a model to generate data for iterative testing and modification of a  proposed object, tool, or process such that an optimal design can be achieved.  Common Core Standards:MathematicsMP.2.        Reason abstractly and quantitatively._______________________________________________________________________________________________Water Quality Debate/ 60 minutes (Class- Fall, Winter, Spring):Students will demonstrate how disputes regarding water quality and quantity can be settled through mediation by playing character roles in a mock Town Hall Meeting. They will develop and engage in an evidence supporting argument surrounding a local water-related issue, evaluate arguments presented by others of different viewpoints, and decide on a resolution.Science Standards:MS-LS2-5.    Ecosystems: Interactions, Energy and Dynamics: Evaluate competing design solutions for maintaining biodiversity and ecosystem servicesCommon Core Standards:ELA/LiteracyMS-LS-2-2.    Engage effectively in a range of collaborative discussions (one on one, in groups, and teacher led) with diverse partners on grade 8 topics, texts, and issues, building on other’s ideas and expressing their own clearly. MS-LS2-2.    Present claims or findings, emphasizing salient points in a focused coherent manner with relevant evidence, sound valid reasoning and adequate well-chosen details, use appropriate eye contact, adequate volume, and other pronunciation. 

The original Native American story component lesson was developed as part of an Office of Superintendent of Public Instruction (OSPI) and Washington State Leadership and Assistance for Science Education Reform (LASER) project funded through an EPA Region 10 grant. The stories were told by Roger Fernandes of the Lower Elwha Klallam tribe. Mr. Fernandes has been given permission by the tribes to tell these stories.As these lessons and stories were shared prior to the adoption of the Washington State Science Learning Standards in 2013, there was a need to align these stories with the current science standards. This resource provides a current alignment and possible lesson suggestions on how these stories can be incorporated into the classroom. This alignment work has been funded by the NGSS & Climate Science Proviso of the Washington State Legislature as a part of North Central Educational Service District's award.

Students apply their understanding of the natural water cycle and the urban "stormwater" water cycle, as well as the processes involved in both cycles to hypothesize how the flow of water is affected by altering precipitation. Student groups consider different precipitation scenarios based on both intensity and duration. Once hypotheses and specific experimental steps are developed, students use both a natural water cycle model and an urban water cycle model to test their hypotheses. To conclude, students explain their results, tapping their knowledge of both cycles and the importance of using models to predict water flow in civil and environmental engineering designs. The natural water cycle model is made in advance by the teacher, using simple supplies; a minor adjustment to the model easily turns it into the urban water cycle model.

Through an overview of the components of the hydrologic cycle and the important roles they play in the design of engineered systems, students' awareness of the world's limited fresh water resources is heightened. The hydrologic cycle affects everyone and is the single most critical component to life on Earth. Students examine in detail the water cycle components and phase transitions, and then learn how water moves through the human-made urban environment. This urban "stormwater" water cycle is influenced by the pervasive existence of impervious surfaces that limit the amount of infiltration, resulting in high levels of stormwater runoff, limited groundwater replenishment and reduced groundwater flow. Students show their understanding of the process by writing a description of the path of a water droplet through the urban water cycle, from the droplet's point of view. The lesson lays the groundwork for rest of the unit, so students can begin to think about what they might do to modify the urban "stormwater" water cycle so that it functions more like the natural water cycle. A PowerPoint® presentation and handout are provided.

Students learn about the techniques engineers have developed for changing ocean water into drinking water, including thermal and membrane desalination. They begin by reviewing the components of the natural water cycle. They see how filters, evaporation and/or condensation can be components of engineering desalination processes. They learn how processes can be viewed as systems, with unique objects, inputs, components and outputs, and sketch their own system diagrams to describe their own desalination plant designs.

In this lesson, students learn about extreme weather, create an infographic, and educate others on the knowledge gained from this unit.

Step 1 - Inquire: Students watch videos to understand why weather is becoming more extreme.

Step 2 - Investigate: Students create an infographic about extreme weather impacts in their area.

Step 3 - Inspire: Students educate others on the knowledge gained from this unit.

A computer simulator that allows students to adjust the air temperature and dew point to see what type of precipitation would fall to the ground.

This series of ten lessons has been developed to teach students about local and global water issues. They are based on NASA’s Global Precipitation Measurement (GPM) Mission. The activities are done largely outdoors and include scientific data collection and analysis and integrate technology. Many of the lessons involve data collected based on protocols from the GLOBE Program. Each lesson is designed to take one hour; the lessons build on each other, but can also be used independently. Each lesson topic includes a lesson plan, PowerPoint presentation, student capture sheet and capture sheet answer guide.

In this lesson, students learn about transpiration and how transpiration plays a role in cooling cities that experience extreme heat due to climate change.

Step 1 - Inquire: Students explore the idea of transpiration through a hands-on experiment.

Step 2 - Investigate: Students learn about trees' connection to urban heat island.

Step 3 - Inspire: Students create a proposal to improve tree equity in their neighborhoods.

Groundwater is one of the largest sources of drinking water, so environmental engineers need to understand groundwater flow in order to tap into this important resource. Environmental engineers also study groundwater to predict where pollution from the surface may end up. In this lesson, students will learn how water flows through the ground, what an aquifer is and what soil properties are used to predict groundwater flow.

Engineers design and implement many creative techniques for managing stormwater at its sources in order to improve and restore the hydrology and water quality of developed sites to pre-development conditions. Through the two lessons in this unit, students are introduced to green infrastructure (GI) and low-impact development (LID) technologies, including green roofs and vegetative walls, bioretention or rain gardens, bioswales, planter boxes, permeable pavement, urban tree canopies, rainwater harvesting, downspout disconnection, green streets and alleys, and green parking. Student teams take on the role of stormwater engineers through five associated activities. They first model the water cycle, and then measure transpiration rates and compare native plant species. They investigate the differences in infiltration rates and storage capacities between several types of planting media before designing their own media mixes to meet design criteria. Then they design and test their own pervious pavement mix combinations. In the culminating activity, teams bring together all the concepts as well as many of the materials from the previous activities in order to create and install personal rain gardens. The unit prepares the students and teachers to take on the design and installation of bigger rain garden projects to manage stormwater at their school campuses, homes and communities.

This activity was developed to give participants an understanding of Earth's water cycle by completing a WebQuest and building a model of the water cycle.

The water cycle game helps you learn how water molecules move through various places including rivers, the ocean, the earth’s surface, the atmosphere and clouds. Actions such as evaporation, runoff, condensation, precipitation, soil absorption and ground water expansion move water from one zone to another.

In this lesson, students learn about the water cycle and how climate change impacts its patterns.

Step 1 - Inquire: Students contemplate their relationship with water and observe a demonstration to determine if shifting climates may affect the water cycle.

Step 2 - Investigate: Students explore an interactive diagram about the water cycle.

Step 3 - Inspire: Students watch a video and complete a series of questions in their student journals.

Students learn about floods, discovering that different types of floods occur from different water sources, but primarily from heavy rainfall. While floods occur naturally and have benefits such as creating fertile farmland, students learn that with the increase in human population in flood-prone areas, floods are become increasingly problematic. Both natural and manmade factors contribute to floods. Students learn what makes floods dangerous and what engineers design to predict, control and survive floods.

In this activity, students act as water molecules and travel through parts of the water cycle (ocean, atmosphere, clouds, glaciers, snow, rivers, lakes, ground, aquifer). Students use a diagram of the hydrologic cycle to draw the pathway they traveled.

During this live chat we discussed the solstice and answered your questions about the Sun.

The best way for students to understand how groundwater flows is to actually see it. In this activity, students will learn the vocabulary associated with groundwater and see a demonstration of groundwater flow. Students will learn about the measurements that environmental engineers need when creating a groundwater model of a chemical plume.

Students learn about the Earth's water cycle, especially about evaporation. Once a dam is constructed, its reservoir becomes a part of the region's natural hydrologic cycle by receiving precipitation, storing runoff water and evaporating water. Although almost impossible to see, and not as familiar to most people as precipitation, evaporation plays a critical role in the hydrologic cycle, and is especially of interest to engineers designing new dams and reservoirs, such as those that Splash Engineering is designing for Thirsty County.

This lesson will help students understand how to work as a forensic meterologist. Students will watch a short video of an area experiencing increased weather and storms. Through the use of prompts, students will be able to create a model of what they think is happening and then use that pre-model in other lessons to figure out how water and heat from the sun increase stroms.